TABLE 1

Nafion ®

PBO (poly(bisbenzoxazole-1,4-phenylene)

PBT (poly(benzo(bis-thiazole)-1,4-phenylene))

PBI (poly(benzo(bis-diazole)-1,4-phenylene)

PAR (polyaramid or Kevlar ®)

PPSO₂(polyphenylene sulfone)

TABLE 2

PSU (polysulfone) (Udel ®)

PES (polyether sulfone)

PEES (polyether-ether sulfone)

PAS (polyarylether sulfone) or PPSU (polyphenyl sulfone)

TABLE 3

PI (polyimide) or poly(pyromellitic dianhydride/para phenylene diamine)

PPO (poly(2,6 dimethyl 1,4 phenylene oxide))

PPSO (polyphenylene sulfoxide)

PPS (polyphenylene sulfide)

PPS/SO₂ (polyphenylenesulfide sulfone)

PPP (polyparaphenylene)

PPQ (poly (phenylquinoxaline))

PEK (polyetherketone)

PEEK (polyetheretherketone)

PEKK (polyetherketoneketone)

PEEKK (polyetheretherketone- ketone)

PEKEKK (polyetherketone- etherketone-ketone)

TABLE 4

PEI (polyetherimide) R = aryl, alkyl, aryl ether or alkylether

Polysulfone (Udel ®)

Polyphenylsulfone (Radel R ®)

Polyethersulfone (Radel A ®)

Polyether sulfone (Ultrason E ®)

Poly(hexafluoroisopropylidine dianhydride/meta phenylene diamine)

Poly(triphenylphosphine oxide sulfide- phenylsulfone-sulfide)

Poly(2-phenylsulfide-1,4-phenylene)

Poly(hexafluoroisopropylidene dianhydride/diaminodiphenyl sulfone)

(PVSA) polyvinyl sulfonic acid

Poly(hexafluoroisopropylidene dianhydride/diaminodiphenoxybenzene)

Poly-X ® (Maxdem)

Poly(pyrolmellitic diimide-1,3-phenylene)

Poly(diphthalimide-1,3-phenylene)

(PPO) poly(1,4-phenylene oxide)

Diphenyl PPO (poly(2,6-diphenyl-1,4- phenylene oxide)

PBPS (poly(benzophenone sulfide))

Poly(benzophenone sulfide- phenylsulfone-sulfide)

Poly(acrylic acid)

Poly(trifluorostyrene sulfonic acid)

Poly(vinyl phosphonic acid)

Poly(styrene sulfonic acid) (PSSA)

TABLE 5

									1 M Me(OH)
									Permeability
									(×10⁻⁶)	Dim.
			Thickness	% Dry Vol		Water	Resistance		Moles CO₂per	Stability
Serial	ICP Type	ICP	(mils)	ICP	IEC	Content	(ohm *	Peroxide	min per cm²	(% Area

Number	(ID)	(% wt)	Dry	Wet	(Estimated)	(meq./g)	(%)	m²)	Test	per mil	Change)

Nafion	Nafion 117	100	7.1	8.7	100	0.90	38	0.203	−3.2%	1.74	~20%
117	(1100 EW)
Control
FMI	75% SPSU	~30	NT	1.5	49	0.55	45	0.056	NT	NT	NT
539-22-1	(Udel)
FMI	75% SPSU	~30	NT	1.5	49	0.96	55	0.043	NT	NT	NT
539-22-2	(Udel)
FMI	100%	~30	NT	2.0	49	NT	NT	NT	NT	0.187	NT
539-22-3	SPSU
	(Udel)
FMI	75% SPES	12	2.0	3.1	29	0.23	27	127.0	−38%	NT	NT
126-08E	(Ultrason
	E)
FMI	75% SPES	8	1.6	1.8	19	0.07	30	2177.1	−36%	NT	NT
126-08F	(Ultrason
	E)
FMI	1100 EW	10	0.8	0.9	16	0.29	43	1290.8	NT	NT	nil
126-16N	(DuPont)
FMI	1100 EW	10	0.9	1.0	16	0.39	32	1183.2	NT	NT	nil
126-16O	(DuPont)
FMI	150%	20	1.1	3.5	40	0.82	87	5.11	NT	NT	nil
126-17P	SPPSU
	(Radel R)
FMI	100%	20	1.2	2.5	40	0.62	60	16.60	NT	0.073	nil
126-17Q	SPPSU
	(Radel R)
FMI	150%	20	2.1	4.7	40	0.54	90	1.85	−63%	NT	nil
126-18T	SPPSU
	(Radel R)
FMI	100%	20	3.1	3.7	40	0.50	92	16.34	−56%	0.179	nil
126-18U	SPPSU
	(Radel R)
FMI	200%	20	1.2	2.0	94	1.66	138	0.292	NT	NT	nil
126-	SPPSU
AY1	(Radel R)
FMI	1100 EW	~17	2.0	2.5	40	1.16	47	0.637	NT	NT	nil
126-	(Dupont)
79BB
FMI	200%	20	1.0	1.5	94	0.91	143	0.140	NT	0.261	nil
126-	SPPSU
82BE	(Radel R)
FMI	200%	8	1.1	2.0	79	1.13	64	0.263	NT	NT	nil
126-	SPPSU
d91BO	(Radel R)

NT = NOT TESTED

EXAMPLES OF THE INVENTION

The polymers described herein are commercially available from a variety of suppliers (unless otherwise indicated). Suppliers of these polymers include the following: RTP, Ticona, Alpha Precision, Polymer Corp., Amoco Polymers, Greene Tweed, LNP, Victrex USA, GE Plastics, Norton Performance, BASF, Mitsui Toatsu, Shell, Ashley, Albis, Phillips Chemical, Sumitomo Bake, Sundyong, Ferro, Westlake, M. A. Hanna Eng.

The following procedures were employed in the fabrication and testing of samples that were prepared in accordance with the membranes and methods of this invention.

General Procedures

IEC Procedure

1. Cut out pieces of sulfonated films (target weight 0.2 g, target film thickness 2 mils).

2. Vacuum dry films at 60° C., record dry weights and note if films are in H+ or Na+ form.

3. Boil deionized water in separate beakers on hotplate.

4. Place films into boiling water.

5. Boil films vigorously for ½ hour.

6. Prepare 1.5N H₂SO₄.

7. Place films into H₂SO₄and soak for ½ hour.

8. Remove films and rinse with deionized water.

9. Boil in deionized water again. Repeat until the films have soaked in H₂SO₄three times.

10. Remove films from boiling water, pat film surface with paper towel, and rinse carefully with deionized water.

11. Place films in another beaker of water and check for pH.

12. Continue to rinse the films with water until pH is neutral to remove any excess acid trapped in the folds of the film.

13. Prepare saturated NaCl solution.

14. Boil the NaCl solution, pour into screw cap vials, add film and cap.

15. Place capped vials with film into water bath at 90° C. for 3 hours.

16. Remove capped beaker from water bath and cool to room temperature.

17. Remove the films from NaCl solution by pouring the salt solution into another beaker (save), wash the films with deionized water (save all washings—they will be used for titration).

18. Titrate the NaCl solution with 0.1N NaOH.

19. Take the films, pat with paper towel and take wet weight. (Use wet weight to determine water content of films.)

20. Dry the films under vacuum at 60° C. until constant weight.

21. Take dry weight and use this to calculate IEC.

Peroxide Test Procedure

22. Place films into the H+ form by following steps 1-12.

23. Make peroxide solution by adding 4 ppm Fe to 3% hydrogen peroxide (28.5 mg of ammonium iron (II) sulfate hexahydrate per liter of peroxide obtained from Aldrich).

24. Place the peroxide solution into water bath at 68° C.

25. Add films to the peroxide solution already at 68° C.

26. Peroxide test for 8 hours and record film properties (mechanical, color, handling etc.).

27. If film passes, remove from peroxide, rinse with water to remove all traces of peroxide solution.

Follow steps 13-21 to obtain post-peroxide test IEC.

Crosslinking Procedures

Ion-conducting polymeric samples can be crosslinked in the acid (H+) form to improve ICP stability. Normally, crosslinking is performed in vacuum, to exclude oxygen from the system (which can cause ICP charring). The vacuum oven should be preheated to temperatures of at least about 200° C. The ICP sample is then heated in the vacuum oven for a prolonged period of time. The ICP sample should be tested before and after crosslinking for IEC and peroxide stability in order to evaluate long term membrane stability. See e.g., Example 15 below.

Film Fabrication Procedures

Film Casting:

Unoriented, microporous substrate films can be made by dissolving the polymer in a suitable water miscible solvent and casting onto a glass plate or other surface. For example, dry PBO polymer can be dissolved in methanesulfonic acid (MSA). The films are slowly placed into a water bath, where solvent is rinsed from the films forming microporous, water-swollen membranes of PBO polymer. Subsequent washing allows for removal of all traces of the solvent.

Extrusion:

In general, the extrusion of a polymer solution (in a water miscible solvent) followed by its coagulation and washing in a water bath allows the formation of microporous polymer films. The mechanical properties and porosity are controlled by the characteristics of the polymer solution and the details of the extrusion process.

Microporous, biaxially-oriented films of liquid crystal polymers (LCPs) can be produced using a counter-rotating die (CRD) extrusion process. Solutions of the polymer are extruded using two annular and concentric mandrels that rotate in opposite directions. The rotation of the mandrels creates a transverse shear flow that is superimposed on the axial shear developed as the polymer solution is extruded through the die. The angle that the LCP fibrils make with the longitudinal axis of the tubular extrudate is ±θ, where θ can be varied from near-zero to about 65 degrees. The die rotation presets the biaxial (±θ) orientation of the emerging extrudate.

Subsequent post-die blowout (radial expansion) and draw (extrusion direction stretching) are used to further adjust and enhance the biaxial orientation.

The tubular extrudate leaving the die is expanded radially (blown) with pressurized nitrogen and stretched in the machine direction by pinch rolls to achieve the desired film thickness. The blown and drawn PBO bubble is immediately quenched in a water bath where the film structure is coagulated, or “locked-in-place”, and the polyphosphoric acid is hydrolyzed into phosphoric acid. The PBO film is collected under water on a spool, which is later transferred to a fresh water storage tank where it is thoroughly rinsed and stored in the water-swollen state until needed.

See e.g., U.S. Pat. No. 4,963,428.

Hot Pressing of LCP Membranes

A slug of LCP dope of a mass sufficient to yield a film of desired thickness and diameter is placed between a sheet of Mylar and a sheet of Teflon, with shims of desired thickness on the perimeter. This assembly is made within a hinged clam mold resting inside a vacuum press. Once evacuated, the sample is pressed to 20,000 lbs. at up to 105-100° C. and held at these conditions for 10 minutes. Pressure is then maintained while the press and sample are cooled to room temperature at a 25 degree per minute rate. The sample is removed from the press, and the Teflon is peeled off before mounting the sample in tensioning rings and immersing it in water to coagulate it.

Solvent Exchange:

The water swollen microporous substrate is used to complete a staged “solvent” exchange. The initial solvent (100% water) is exchanged for the desired solvent (e.g. NMP, alcohol, etc.) in a number of stages. To minimize the collapse of the pores, the exposure of the substrate film to the air is minimized. For example, note the 5 part exchange from water to NMP as follows:


	START	FINISH

Exchange #1:	100% Water	75% Water/25% NMP
Exchange #2:	75% Water/25% NMP	50% Water/50% NMP
Exchange #3:	50% Water/50% NMP	25% Water/75% NNP
Exchange #4:	20% Water/80% NMP	100% NMP
Exchange #5:	100% NMP	Fresh (anhydrous) NMP

Microporous substrate films are stored in the exchanged solvent until they are used in composite SPEM formation.

Sulfonation Procedures

Sulfonation Procedure I:

Aromatic PES polymers can be sulfonated to controlled degrees of substitution with sulfonating agents. The degree of substitution is controlled by the choice of and mole ratio of sulfonating agent to aromatic rings of the polymer, by the reaction temperature and by the time of the reaction. This procedure offers a method for carrying out sulfonation in a heterogeneous manner, i.e., sulfonation of precipitated polymer crystals.

The polymer (preferably a polyethersulfone) is first dissolved in the appropriate solvent (preferably methylene chloride) and then allowed to precipitate into a fine crystalline suspension. Sulfonation is carried out by simple admixture of the suspension with a sulfonating agent. Suitable agents include chorosulfonic acid and, preferably, sulfur trioxide (Allied chemicals stabilized Sulfan B® in CH₂Cl₂). The sulfonating agent used should be in sufficient proportion to introduce a number of sulfonate groups onto the polymer that is within the range of between 0.4:1 to 5:1 per polymer repeat unit, although this is not critical. The temperature at which sulfonation takes place is critical to limiting the side reactions but varies with the type of polymer (a preferable temperature is within the range of from −50° to 80° C., preferably −10° to +25° C.).

When the desired degree of sulfonation has been reached, the sulfonated polymer may be separated from the reaction mixture by conventional techniques such as by filtration, washing and drying.

The polymer products of the process of the invention may be neutralized with the addition of a base, such as sodium bicarbonate, when desired and converted to the alkali salts thereof. The alkali salts of the polymer products of the invention may be used for the same purposes as the parent acid polymers.

See e.g., U.S. Pat. No. 4,413,106.

Sulfonation Procedure II:

Concentrated sulfuric acid is used as the solvent in this procedure. The content of the sulfonating agent, sulfur trioxide, is based on the total amount of pure (100% anhydrous) sulfuric acid present in the reaction mixture, and is kept to a value of less than 6% by weight throughout the entire sulfonation. The sulfur trioxide may be mixed in dissolved form (oleum, fuming sulfuric acid) with concentrated sulfuric acid. The concentration of the starting sulfuric acid and oleum were determined by measuring their density immediately before use in the reactions.

The temperature of the reaction mixture is kept at less than +30° C. throughout the reaction. The sulfonation procedure is stopped by pouring the reaction mixture into water.

More specifically, the polymer is first dried in high vacuum at room temperature to constant weight, then dissolved in concentrated sulfuric acid. Oleum is then added drop-wise over a period of hours with constant cooling below +30° C., and with stirring. When all of the oleum has been added, the reaction mixture is stirred for a further period of hours at the same temperature. The resultant viscous solution is then run into water and the precipitated polymer is filtered off. The polymer is then washed with water until the washings no longer are acidic, and it is then dried.

If these conditions are maintained, a controllable sulfonation of aromatic polyether sulfones is possible and polymer degradation can be substantially or completely prevented.

Though less preferred, another variation of this procedure is to add the sulfur trioxide either in pure solid state or in gaseous state to a solution of the polymer in concentrated sulfuric acid.

See e.g., U.S. Pat. No. 5,013,765.

Sulfonation Procedure III:

This sulfonation procedure is directly analogous to procedure I, however, the polymer remains in solution at least until the addition of the sulfonating agent.

Polymer is first dissolved in a solvent that is compatible with the sulfonating agent (e.g. methylene chloride) in a nitrogen atmosphere. The sulfonating agent is added to this solution over the course of several hours. The resulting solution or suspension (if the polymer precipitates as the reaction occurs) is allowed to react, again for several hours.

When the desired degree of sulfonation has been reached, the sulfonated polymer may be separated from the reaction mixture by conventional techniques such as by filtration, washing and drying. If the sulfonated polymer remains in solution, the solvent can be removed simply by evaporation or precipitation into a non-solvent.

Membrane Preparation

Microporous substrate films previously exchanged into the appropriate solvent are placed consecutively into solutions of the various ion-conducting polymers (ICP) with increasing concentration (in the same solvent as the unfilled microporous substrate). This technique is known in the art (see, e.g., U.S. Pat. No. 5,501,831). Generally the use of smaller changes in ICP concentration seems to allow the formation of composite films with higher final ICP loadings. In the case of more viscous polymer solutions, the microporous substrates and the imbibing solution are heated (up to 100° C.). Once imbibed with the ICP, the composite film is placed between 6″ diameter tension rings. As the rings are bolted together, the composite is carefully stretched to eliminate any veins or defects in the substrate. Once the rings are completely bolted together, the setup is left to air dry (e.g. in the hood) overnight. This will usually remove much of the excess ion-conducting polymer's solvent by evaporation.

The films are further dried by one of two methods. For low boiling solvents the composite films are heated under vacuum with pressure (about 100 psi) to prevent blistering of the films. In these instances porous, Teflon® coated shims are used to allow the solvent vapor to escape. Higher boiling composite films are simply heated under vacuum past the boiling point of the solvent. The overall uniformity of the final composite membrane can be improved by further pressing these composites at elevated temperature and pressure.

Composite Membrane Testing Methods

IEC. % Water Content, Membrane Degradation:

During this procedure, films are immersed in distilled H₂O and boiled for a period of 30 minutes. The films are then placed in a solution of 1.5N H₂SO₄at room temperature and soaked for a period of 30 minutes. This is repeated three separate times to ensure proper H+ ion exchange into the membrane. Films are rinsed free of acid (pH of rinse water >5.0) and placed into separate beakers, each filled with a saturated solution of NaCl. The salt solution is boiled for a period of three hours. The films, which are now in the Na+ form, are removed from the salt solution, rinsed with distilled water and padded to remove excess water. Now a wet weight and thickness of the sample are measured. While in the Na+ form, the films are dried in an air oven at a temperature of 60° C. The dry weight and thickness of the films are measured and the percent water content is calculated. The salt solutions are titrated with 0.1N NaOH to a phenolphthalein endpoint and IEC dry (meq/g) values calculated.

Ionic Conductivity:

Transverse ionic conductivity measurements are performed on film samples in order to determine the specific resistance (ohm*cm²). Prior to the ionic conductivity measurements, film samples are exchanged into the H+ form using the standard procedure discussed above. To measure the ionic conductivity, the film samples are placed in a die consisting of platinum-plated niobium plates. The sample size tested is 25 cm². Prior to assembling in the measuring device, platinum black electrodes are placed on each side of the film sample to form a membrane-electrode assembly (MEA). To insure complete contact during the resistivity measurement, the MEA is compressed at 100 to 500 psi. The resistance of each film is determined with a 1000 Hz, low current (1 to 5A) bridge, four point probe resistance measuring device and converted to conductivity by using formula 1.
C=t/R×A (1)

- Where: C=Conductivity (S/cm)
  - R=Sample Resistance (ohm)
  - t=Wet sample thickness (cm)
  - A=Sample area (cm2)

Measurements are converted to specific resistance by calculating the ratio of thickness over conductivity (ohm*cm²).

Membrane Degradation:

Accelerated degradation testing is carried out using 3% H₂O₂solution with 4 ppm Fe++ added as an accelerator. The films are tested for a period of 8 hours at a temperature of 68° C. The percent degradation of IEC was measured in the film samples after the test. After 8 hours, the films are removed from solution, and re-exchanged using 1.5 N H₂SO₄. The IEC is recalculated, and the test result expressed as the % loss in IEC. This test simulates long term (several thousand hours) of actual fuel cell operation. For H₂/O₂, fuel cells, <10% IEC degradation in this test would be considered acceptable.

Example 1

Sulfonation of Radel R®

Using Sulfan B® (100% and 150% Stoichiometric Sulfonation)

Sulfonation Procedure I was used in the following example.

Two separate 1000 ml 3 neck resin kettles (with ribs) equipped with an N₂inlet, addition funnel, and overhead stirrer were charged with the following reactants: 340 ml of dichloromethane and 50.00 grams of Radel R® Polyphenylsulfone Polymer (beads). These mixtures were stirred until solutions formed (approximately 0.25 hours). Once solutions formed, they were cooled in ice baths to about a temperature of 0° C. (ice bath was maintained throughout the duration of the addition and reaction). (Note that Radel R® was dried at 70° C. under full dynamic vacuum for about 12 hours to remove any adsorbed moisture.)

While the above solutions were cooling, the following amounts of Sulfan B® were combined with dichloromethane in two separate 125 ml addition funnels. In funnel #1 (100% sulfonation) 10.00 grams of Sulfan B® was combined with 120 ml of dichloromethane. In funnel #2 (150% sulfonation) 15.00 grams of Sulfan B® was combined with 120 ml of dichloromethane.

As polymer solutions were cooled, the polymer precipitated from solution to form a viscous paste. To each of these polymers approximately 350 ml of dichloromethane was added to aid in the uniform mixing of the suspensions. The diluted suspensions were then cooled to ice bath temperatures once again.

To the rapidly stirring cooled and diluted polymer suspension, the Sulfan B® solutions were added drop-wise over a period of 3.5 to 4.0 hours.

Upon completing the addition of the Sulfan B®/dichloromethane solution, the reaction mixtures were permitted to stir at ice bath temperatures for another 2.5 hours, then the reaction was stopped by adding approximately 10 ml of deionized water to each of the reaction mixtures.

The reaction mixtures (white dispersions) were recovered by filtration using a glass frit. Products (white powder) were washed 3× with 100 ml portions of dichloromethane. The washed products were then permitted to air dry in the hood. 20% solutions of the dried products were made in NMP and cast on soda lime glass plates. The freshly cast films were left to stand in a dry box with a relative humidity of less than 5% for a period of 24 hours. The cast films were heated at 70° C. under full dynamic vacuum for an hour prior to floating the films off with deionized water. The floated films were then permitted to air dry overnight.

The 100% and 150% sulfonated products swell greatly in water and become opaque, but when films are dry they shrink and become clear once again. The mechanical strength of these films allows creasing while resisting tearing. Films of the 100% and 150% products are not soluble in boiling water, and under these conditions also maintain their mechanical properties.

- IEC: 100% sulfonated Radel R® unpurified=1.39 meq./g
  - 150% sulfonated Radel R® unpurified=1.58 meq./g

These polymers were further purified by dissolving in NMP (at 20 wt. %) and then precipitated into a large excess of saturated salt water. The resulting polymers were soaked in sodium bicarbonate, washed several times with water, then dried under vacuum (˜100° C.). These polymers were also cast into films as described above for characterization.

- IEC: 100% sulfonated Radel R® purified=1.26 meq./g
  - 150% sulfonated Radel R® purified=1.44 meq./g
- Water Pick-up (wt. %):
  - 100% sulfonated Radel R® purified=56%
  - 150% sulfonated Radel R® purified=110%

Example 2

Sulfonation of Radel R®

Using Sulfan B® at 200% Stoichiometric Sulfonation

Procedure:

This sulfonation reaction was run very similarly to those previously described in Example 1 (100, 150% sulfonations with Sulfan B®), with minor adjustments, which are noted below:

After the precipitation of the polymer from the initial dichloromethane solutions, only 200 ml of new solvent was added to enhance stirring (in Example 1, an additional 350 ml was used).

Previous data suggests that not all of the SO₃reacts with the polymer over 6 hours at 0-5° C. Therefore, one reaction was carried out at ice bath temperatures for 8 (or more) hours and then allowed to warm to room temperature. Although the resulting sulfonated Radel R® was darker in color than the batch that was quenched after only 6 hours, the polymer was still water insoluble and showed good film properties. The properties of such ICPs are:

- 200% Sulfonated Radel R (quenched after 6 hrs at 0-5° C.):
- IEC=1.67 meq/g, Water Pick-up=144%, Conductivity=0.073 S/cm.
- 200% Sulfonated Radel R (quenched after allowed to warm up):
- IEC=1.90 meq/g, Water Pick-up=174%, Conductivity=0.091 S/cm

Note: Percent sulfonation in terms of stoichiometry, e.g., 200% sulfonation, refers to the use of a particular excess per each polymeric repeat unit, e.g., two moles in the case of 200% sulfonation.

Example 3

Sulfonation of BASF Ultrason® Polyether Sulfone

Using Sulfan B®

(85%, 75%, and 65% Sulfonation)

Sulfonation Procedure III was used in the following example.

Three separate 1000 ml 3 neck resin kettle (with ribs) equipped with an N₂inlet, addition funnel, and overhead stirrer were charged with the following reactants: the first resin kettle was charged with 350 ml of dichloromethane and 51.00 grams of BASF Ultrason polyether sulfone polymer (fine powder), the second was charged with double the amount of reactants, and the third was charged with the same ratios as the first. Ultrason was dried at 70° C. under dynamic vacuum for about 12 hours prior to use. These mixtures were stirred until solutions formed (approximately 15 min.). Once solutions formed, they were cooled in ice baths to about a temperature of 0° C. (ice bath was maintained throughout the duration of the addition and reaction).

While the above solutions were cooling, the following amounts of Sulfan B® were combined with dichloromethane in three separate 125 ml addition funnels. In funnel #1 (85% sulfonation) 14.94 grams of Sulfan B® were combined with 120 ml of dichloromethane. In addition funnel #2 (75% sulfonation) 26.32 grams of Sulfan B® were combined with 120 ml of dichloromethane. In addition funnel #3 (65% sulfonation) 11.80 grams of Sulfan B® were combined with 120 ml of dichloromethane. These solutions were then added dropwise to the corresponding rapidly stirring cooled polymer solutions over a period of 4 hours.

Addition of the Sulfan B® solution caused the polymer to precipitate and form a very viscous sludge. These were diluted with the following amounts of anhydrous dichloromethane. Reaction #1 was diluted with 70 ml of anhydrous dichloromethane, #2 was diluted with 600 ml of dichloromethane, and #3 was diluted with 400 ml of dichloromethane. Upon completing the addition of the Sulfan B®/dichloromethane solution, the reaction mixture was permitted to stir and warm to room temperature overnight. The following morning the reaction mixtures (a white dispersion) were filtered using a glass frit. Products (a fine white powder) were washed 3× with 100 ml. portions of dichloromethane. The washed products were then permitted to air dry in the hood for 4 hours.

20 wt. % solutions of the dried products were made in NMP. The polymer solutions were filtered using a 2.5 micron glass fiber filter cartridge. The filtered products were then precipitated into approximately 4 liters of water. These products were then washed 2× with deionized water. The washed products were converted into the sodium form by soaking in a 2.5% sodium hydroxide solution over several days. These were then washed with deionized water until a neutral pH was achieved. Finally, the samples were thoroughly dried in vacuum.

When 85% sulfonated polymer is boiled in water, it swells greatly and partially dissolves. The 75% and 65% sulfonated products do not dissolve in boiling water, however they showed considerable swelling.

- IEC: 65% sulfonated Ultrason purified=0.69 meq./g
  - 75% sulfonated Ultrason purified=0.80 meq./g
  - 85% sulfonated Ultrason purified=1.08 meq./g
- Water Pick-Up (wt. %):
  - 65% sulfonated Ultrason purified=18%
  - 75% sulfonated Ultrason purified=21%

Example 4

Synthesis of Sulfonated Udel® Polyether Sulfone

Using Chlorosulfonic Acid (33-100% sulfonation)

Sulfonation Procedure III was used in the following example.

Procedure:

A 1000 ml. 3 neck round bottom flask equipped with a condenser, N₂inlet, and overhead stirrer; was charged with 175 ml of dichloromethane and 50.0 grams of Udel® Polyethersulfone. This mixture was stirred until a solution formed (approximately 3 hours).

While the above was stirring 11.49 grams of chlorosulfonic acid was mixed with 50 ml. of dichloromethane in a 125 ml. addition funnel. This solution was added dropwise to the rapidly stirring polymer solution over a period of an hour. The reaction mixture changed from a clear amber color to a cloudy caramel color. Upon completing the addition the acid solution, the reaction mixture was permitted to stir at room temperature over night.

After stirring at room temperature for 28 hours the reaction mixture was heated in a water bath until a mild reflux was achieved, and it was kept refluxing under these conditions for an hour. After heating the reaction mixture for an hour the heat source was removed and the mixture was permitted to cool.

After removal of the solvent, the product was dissolved in THF. Films cast from this solution were transparent and creasible. IR spectra and water absorption were consistent with the formation of sulfonated Udel® Polyethersulfone.

Complete reaction of the chlorosulfonic acid corresponds to the addition of 0.85 sulfonate groups per repeat unit of the polymer (85%). Similarly, sulfonated versions of Udel® Polyethersulfone were made with levels of sulfonation from 33 to 100%.

- IEC: 75% sulfonated Udel=1.10 meq./g
  - 85% sulfonated Udel=1.19 meq./g
- Water Pick-up (wt. %):
  - 75% sulfonated Udel=12%
  - 85% sulfonated Udel=93%

Example 5

Synthesis of Sulfonated-Polyimides

(via Monomers)

Sulfonation procedures described by Sillion [French patent 9,605,707] were used as a guide in the following example. However, alternate monomers and reaction conditions were employed.

Sulfonated polyimides are produced by the reaction of a sulfonated diamine with a dianhydride, using a 1.000 molar ratio of diamine/dianhydride, in a solvent under an inert atmosphere. An exact diamine/dianhydride molar ratio of 1.000 is required in order to achieve high molecular weight polymers. Polyimides are synthesized through an intermediate polyamic acid form which contains an amide linkage and carboxylic acid groups. This polyamic acid may or may not be isolated from the reaction solution. The polyamic acid is converted to the corresponding polyimide by a cyclization reaction involving the amide hydrogen and neighboring carboxylic acid groups, forming a five (or six) membered imide ring, with the evolution of water as a reaction byproduct.

Polyimides can be made via two general procedures: 1) first synthesize, at or below ambient temperatures its solvent-soluble polyamic acid form, then chemically or thermally transform this polyamic acid to the polyimide; and 2) directly synthesize the solvent-soluble polyimide using reaction temperatures in excess of 100° C. to distill water from the initial reaction solution. Each of these procedures was used at Foster-Miller to produce sulfonated-polyimides. The details of these reactions are presented below.

Formation of the Sodium Salt of 2,4-Diaminobezenesulfonic Acid (2,4-NaDBS)

2,4-Diaminobenzenesulfonic acid (2,4-DBS) (5.00 grams, 26.6 mmoles) was dispersed in 95.29 grams anhydrous methanol at ambient temperatures under a positive nitrogen atmosphere in a reaction flask equipped with a reflux condenser, magnetic spinbar for stirring purposes and pressure equalizing funnel. A cloudy dispersion of sodium hydroxide (1.06 grams, 26.6 mmoles) in methanol (93.4 grams) at a concentration of 1.1 wt. percent was placed in the pressure equalizing funnel and added dropwise to the stirring 2,4-DBS/methanol dispersion at ambient temperatures. Additional methanol (195 grams) was added to transform the dispersion into a brownish orange colored solution after stirring overnight, containing approximately 1.3 wt. percent solids. Initially, 2,4-DBS was found to be insoluble at similar concentrations in methanol, indicating 2,4-DBS has been converted into a more soluble material. The solution was heated at reflux for several hours to ensure the reaction had gone to completion, cooled to ambient temperatures, and filtered to remove any trace amounts of undissolved material. Hexanes (275 mL) were then added to the solution to precipitate a tannish solid. This solid was collected by filtration, washed with hexanes and air dried. The material exhibited a single reproducible endothermic absorption between 246° to 252° C., with a peak width at half height of 5.3° C. by differential scanning calorimetry. Its infrared spectrum (IR) showed absorptions typical for a —NH₂amine (3426, 3380, and 3333 cm⁻¹), a primary amine (3199 cm⁻¹), aromatic C-Hs (1624 cm⁻¹) and SO₃salt (1230 and 1029 cm⁻¹) groups. These SO₃salt absorptions were located at values different than those observed for HOSO₂in 2,4-DBS, which appeared at 1302 and 1134 cm⁻¹. The amine absorption at 3426 cm⁻¹in this material was also not present in 2,4-DBS. The IR absorption typical for a sulfonic acid (—SO₂—OH) group at 2609 cm⁻¹in 2,4-DBS was also absent. The combination of all this information indicates the tannish solid product is sodium 2,4-diaminobenzenesulfonate (2,4-NaDBS).

This material was be used as an alternative to 2,4-DBS in the synthesis of sulfonated polyimides due to its increased thermal stability and potentially increased reactivity toward polyimide formation (amine groups in the 2,4-NaDBS are more reactive toward the dianhydride monomer due to electron release from the sulfonate group).

Synthesis of the Copolyamic Acid Derived from 6FDA, m-Phenylenediamine (m-PDA) and 2,4-NaDBS (6FDA/m-PDA/2,4-NaDBS PAA)

2,4-DBS (7.75 mmoles) and m-PDA (7.75 mmoles) were easily dissolved in anhydrous dimethylsulfoxide (DMSO) at ambient temperatures under a nitrogen atmosphere. 6FDA (15.5 mmoles) was added all at once to the diamine solution and the mixture was stirred at ambient temperatures under a nitrogen atmosphere. The reaction mixture became warm to the touch as the 6FDA began to dissolve and the resulting, solution was stirred overnight at ambient temperatures. This clear reddish brown solution contained 15.0 wt. percent polymer and exhibited a viscosity similar to warm syrup, indicating polymers with reasonable molecular weights had been produced. The IR spectrum of the reaction solution showed absorptions typical for —NH of an amide (3249 and 3203 cm⁻¹), C=0 amide I stretch (1683 cm⁻¹), aromatic C-Hs (1607 cm⁻¹), N—C=0 amide II symmetric stretch (1548 cm⁻¹) and SO₃salt (1256 and 1020 cm⁻¹). The IR absorption for —OH of HOSO₂at 2609 cm⁻¹was absent from the spectrum. This IR data is consistent with the formation of the 6FDA/m-PDA/2,4-NaDBS copolyamic acid.

A sample of the polyamic acid solution was cast into a film on a NaCl salt IR disc and the film/disc was heated in a circulating air oven for 1 hour each at 100°, 200° and 300° C. to convert the copolyamic acid to its copolyimide form. The IR spectrum of copolyimide film showed absorptions typical for C=0 imide stretch (1787 and 1733 cm−1), aromatic C—H (1603 cm⁻¹), C—N imide stretch (1362 cm⁻¹), HOSO₂acid (1298 and 1145 cm⁻¹), SO₃salt (1256 and 1029 cm⁻¹) and polyimide (745 and 721 cm⁻¹). IR absorptions typical for polyamic acids at 1683 and 1545 cm⁻¹as well as the —OH of HOSO₂at 2609 cm⁻¹were absent. Nevertheless, it appears that some of the NaSO₃groups were converted to HOSO₂by free acid generated during the continuing polymerization.

Thermal Imidization of 6FDA/m-PDA/2,4-NaDBS PAA.

A sample of the reaction solution was cast into a large film with an initial thickness of 0.007 inch on a glass substrate using a motorized film casting table located inside a low humidity chamber (<10 percent relative humidity). The resulting clear copolyamic acid film was heated in a circulating air oven for 1 hour each at 100°, 200°, and 250° C. to form a reddish brown copolyimide film. A final temperature of 250° rather than 300° C. was used to hopefully reduce the thermal degradation of the resulting NaSO₃groups, believed to occur at temperatures >200° C. The copolyimide film broke into many very small pieces upon removal from the glass substrate, a sign that the molecular weight of the copolyimide may be quite low.

Synthesis of the Copolyimide Directly from 6FDA, m-PDA, and 2,4-NaDBS (6FDAlm PDA12,4-NaDBS PI) A brownish dispersion of 2,4-NaDBS (7.47 mmoles) and m-PDA (8.01 mmoles) in m-cresol (50 grams) and anhydrous toluene (20 grams) in a 3-necked flask equipped with a thermometer, mechanical stirrer, and Dean Stark trap fitted with a condenser/nitrogen inlet was heated at about 150° C. under a nitrogen atmosphere. 6FDA (15.49 mmoles) was added to the hot dispersion, whereupon water immediately began to distill out of the reaction dispersion and become collected in the trap. The temperature of the brownish dispersion was gradually increased to about 200° C., maintained at 200° C. for 7.5 hours, and then decreased to ambient temperatures. The resulting dark brown colored, viscous reaction mixture was found to be a dispersion containing significant quantities of crystalline material(s). The IR spectrum of the reaction dispersion showed absorptions typical for or C=0 imide stretch (1781 and 1723 cm⁻¹), C—N imide stretch (1365 cm⁻¹), SO₃salt (1251 and 1033 cm⁻¹), and polyimide (738 and 720 cm⁻¹). The presence of m-cresol in the film prevents determination of whether HOSO₂groups are present due to overlapping absorptions. IR absorptions typical for polyamic acids at 1683 and 1548 cm⁻¹as well as the OH stretch of HOSO₂were absent. IR data indicated some sodium sulfonate-copolyimide had been produced under the reaction conditions, but the presence of a crystalline dispersion rather than solution suggests a significant amount of the diamine was not incorporated into a polymer.

The consistent problem encountered during these reactions was low molecular weight of the final product. The above syntheses did not provide a creasable, sulfonated polymer film. However, fragments of the polymer are unchanged by the peroxide test and have IECs up to 1.13 meq./g.

It is anticipated that higher molecular weight polymer will be obtained by further purifying the 2,4-NaDBS monomer prior to polymerization. In addition, the use of isoquinoline as a polymerization catalyst may accelerate the reaction.

Example 6

Sulfonation of Victrex® Poly(Ether Ketone)

Using H₂SO₄/SO₃

Sulfonation Procedure II was used in the following example.

Procedure:

30.00 g PEK polymer (Victrex®) was dissolved in 270 g of concentrated sulfuric acid (93.5 wt. %) under nitrogen, stirred by an overhead mechanical stirrer. The polymer was dispersed over several days to form a dark red thick solution.

176 g of this solution was left in the three neck flask with overhead stirrer, N₂, etc. To the flask, 208.4 g of fuming sulfuric acid (25.5 wt. % free SO₃) was added over the coarse of a few minutes with constant stirring to raise the solution to a free SO₃content of 2 wt. %. The resulting solution was immersed in a room temperature water bath to control the temperature.

Samples were removed after approx. 1 hour, 3 hours, and 16 hours, and quenched into deionized water to precipitate.

In order to make films, the 1 and 3 hour products were washed several times with deionized water, soaked overnight in approximately 0.5M NaOH solution, then washed until a neutral pH was achieved. These were blotted dry and placed in the vacuum oven overnight at 50° C. Dried samples were dissolved in NMP to make a 20 wt. % solution. This required heating overnight at 60° C. Films of approx. 6 mils were cast onto a freshly cleaned glass plate. After two days of drying the films were removed by immersion into deionized water.

Soaking the films in water (at room temperature) caused considerable swelling to give a hazy gel-like consistency, but the 1 hour and 3 hour samples did not dissolve. Film of the 1 hour product could be hydrated and dehydrated, while maintaining resistance to tearing. The 1 hour sulfonated PEK film IEC was measured to be 2.3 meq/g.

Example 7

Sulfonation of PPS/SO₂Using 97.5% H₂SO₄

Sulfonation Procedure II was used in the following example.

PPS/SO₂provided by James McGrath of VPI [see Synthesis and Characterization of Poly(Phenylene sulfide—sulfone).Polymer Preprints38 (1), 1997, p.109-112].

Procedure:

250 ml 3 neck round bottom flask was equipped with an overhead stirrer, N₂inlet, and addition funnel were charged with 100 grams of 93.5% sulfuric acid. To the rapidly stirring sulfuric acid 25.00 grams of the PPS/SO₂was added. The mixture was stirred at room temperature until a solution formed (approximately 1 hour).

When solution had formed the temperature was lowered to about 0° C., and 60.0 grams of 23.0% fuming sulfuric acid was added dropwise over a period.of a 0.5 hours.

Ice bath temperatures were maintained for the first 3.5 hours of the reaction. Aliquots were taken at T=0.5, 1.5, 2.0, and 3.0 hours by precipitation the reaction mixtures were precipitated into deionized water. Precipitated product appeared not to have swollen to any appreciable extent, so the remaining reaction mixture was warmed to room temperature. Aliquots were taken at t=3:30, 4:30, 7:00, and 8:20 (approximately 4 hours at room temperature).

Products were rinsed 3 times with deionized water, soaked in saturated sodium bicarbonate solution until basic and then washed in deionized water until neutral.

Solubilizing of the sulfonated PPS/SO₂polymers was attempted after drying the precipitated polymer at 100° C. for 3 hours under full dynamic vacuum. The polymer solutions were made with fresh anhydrous NMP and were immediately cast on soda lime glass plates at a thickness of 2 mils. The freshly cast films were placed in a level oven preheated to 100° C. and dried under full dynamic vacuum for 1 hour. After drying (at 100° C.) for an hour, the oven temperature was raised gradually to 200° C. over a period of 3 hours. When the 200° C. was achieved, the oven was shut off and the films were permitted to gradually cool to room temperature. Films were removed from the glass plates by floating them in deionized water.

Based on crude observations of the PPS/SO₂films, this material appears not to have sulfonated to any appreciable extent while kept at 0° C. (little dimensional changes were observed when boiled in water). The PPS/SO₂samples that were reacted at room temperature appear to show some signs of sulfonation (swelling and taking on a rubbery appearance in boiling water).

- IEC sulfonated PPS/SO₂:
  - T=8:20, 0.53 meq./g
- Water Pick-up (wt. %) sulfonated PPS/SO₂:
  - T=8:20, 15%

Increased IECs of the sulfonated PPS/SO₂samples should be possible with increased reaction times.

Example 8

Sulfonation of Poly(phenylquinoxaline)

PPQ was prepared as described in the literature (See e.g.,Macromolecular Syntheses,1974, vol. 5 p. 17), by dissolving equimolar amounts of an aromatic bisbenzildiketone and a bis-o-diamine in a 1:1 mixture of m-cresol and xylene. The resulting polymer was isolated by dilution with chloroform followed by precipitation into a large excess of methanol. The polymer was thoroughly washed with methanol and vacuum dried.

Sulfonation was achieved by first dissolving this polymer in concentrated sulfuric acid, followed by the addition of enough fuming sulfuric acid to react with any water remaining in the system (i.e. 100% H₂SO₄). The resulting solution was heated to 125° C. with constant stirring. Aliquots were taken over 6 hrs. at this temperature. Each aliquot was isolated by precipitation into water, soaking in saturated sodium bicarbonate, followed by several rinsings with deionized water. Sulfonation of the later aliquots was inferred from their enhanced solubility in polar solvent systems. Generally, films cast of the sulfonated PPQ (sodium salt form) are tough, creaseable, and swell in water.

Alternatively, a PPQ film can be soaked in a 50% solution of H₂SO₄for approx. 2 hour in order to fully sulfate it; then baked at a minimum temperature of 300° C. to convert the ammonium sulfate salt to the covalently bonded sulfonic acid. This procedure has been used for the sulfonation of PBI and PPQ films. See e.g., U.S. Pat. No. 4,634,530 and Linkous, et al.,J. Polym. Sci., Vol. 86: 1197-1199 (1998).

Example 9

Fabrication of SPEM

Using PBO and Sulfonated Radel R®

Ion-conducting membranes were fabricated from the polymer substrate film PBO and various sulfonated poly(phenyl sulfones). The substrate utilized was PBO film extruded and solvent exchanged into NMP as described above in the general procedure. The ion-conducting polymer (100, 150% sulfonated Radel R®—Na+ form) was synthesized according to Example 1 given above.

Microporous PBO, having been exchanged into NMP without collapse of the pores, was added to a 5 wt. % solution of the sulfonated Radel R® polymers in NMP. After twelve or more hours, the films were removed and placed in a 20 wt. % solution of the same ion-conducting polymer (also in NMP). After twelve or more hours at room temperature (or at 75° C.) the films were removed, stretched in tensioning rings, and dried of the solvent (see general procedure outlined above). Specifically, the sulfonated Radel R®/PBO films were dried in a low humidity chamber (<5% RH) for 1 to 2 days, vacuum dried in an oven heated from below 60° C. to about 200° C.

After all solvent is fully extracted from the membrane, the composite is preferably hot pressed. The hot pressing operation facilitates flow of the ion-conductor to make a homogenous composite structure. Non-porous Teflon® shims were placed on each side of the composite membrane followed by Titanium shims. The entire setup is then loaded into a press and subjected to the following cycle:

High Temperature Hot Press

Step	Temp.	Hold Time	Force	Ramp Rate

1	392° F.	5 min	1.0 klb	15 F/min
2	392° F.	15 min	28.3 klb	N/A
3	85° F.	5 min	28.3 klb	25 F/min

Note that the 28.3 klbf corresponds to a press pressure of 1000 psi.

SPEMs produced via this example were FMI 126-17P, FMI 126-17Q, FMI 126-17T, FMI 126-17U. See Table 5 for various results obtained from SPEMs made via this procedure.

Example 10

Fabrication of SPEM

Using PBO and Sulfonated Udel®

Ion-conducting membranes fabricated in this example followed closely those in Example 9.

The substrate utilized was PBO film extruded and solvent exchanged into THF as described above in the general procedure. The ion-conducting polymer (75, 85, 100% sulfonated Udel®) was synthesized according to Example 4 given above.

For composite SPEMs of 100% sulfonated Udel® ion-conducting polymer, microporous PBO films exchanged into THF were placed into 30 wt. % solutions of the polymer (in THF) at room temperature. After more than twelve hours, the films were stretched in tensioning rings and allowed to dry in a low humidity chamber. Final traces of the solvent were removed with the following vacuum pressing shown below.

Low Temperature Vacuum Pressing


Step	Temp.	Hold Time	Force	Ramp Rate

1	122° F.	20 min	2.9 klb	15 F/min
2	167° F.	20 min	2.9 klb	15 F/min
3	212° F.	20 min	2.9 klb	15 F/min
4	257° F.	20 min	2.9 klb	15 F/min
5	85° F.	5 min	2.9 klb	25 F/min

The force of 2.9 klb corresponds to a press pressure of 100 psi. Films were finally hot pressed without vacuum to fully consolidate the composite structure, as shown below.

High Temperature Hot Press


Step	Temp.	Hold Time	Force	Ramp Rate

1	317° F.	30 min	28.3 klb	15 F/min
2	85° F.	—	28.3 klb	25 F/min

The force of 28.3 klb corresponds to a press pressure of 1000 psi.

Composite SPEMs were made with both 75 and 85% sulfonated Udelo ion-conducting polymers.

SPEMs produced via this example were FMI 539-22-1, FMI 539-22-2, FMI 539-22-3. See Table 5 for various results obtained from SPEMs made via this procedure.

Example 11

Fabrication of SPEM

Using Solubilized Nafion® 1100 EW

The substrate utilized was PBO extruded film and solvent exchanged into a mixture of water and alcohols (see below) as described above in the general procedure. The ion-conducting polymer used was solubilized Nafion® 1100 EW purchased from Solution Technologies (10 wt. % in a mixture of water and propanols). The solvent system used to exchange the PBO films was made to approximate that of the Nafion® solution.

Composite membranes were made by placing the exchanged films directly into the 10 wt. % Nafion® solutions. After twelve or more hours, these were removed and stretched into tensioning rings as described above. These films were dried in a low humidity chamber for at least 24 hours. Removal of the final traces of solvent were done by placing porous PTFE shims on each side of the composite membrane followed by the Titanium shims. This setup was then loaded into a vacuum press and subjected to the following cycle:

Low Temperature Vacuum Pressing


Step	Temp.	Hold Time	Force	Ramp Rate

1	125° F.	20 min	2.9 klb	15 F/min
2	170° F.	20 min	2.9 klb	15 F/min
3	215° F.	20 min	2.9 klb	15 F/min
4	274° F.	20 min	2.9 klb	15 F/min
5	85° F.	5 min	2.9 klb	25 F/min

High Temperature Hot Press


Step	Temp.	Hold Time	Force	Ramp Rate

1	275° F.	5 min	1.0 klb	15 F/min
2	275° F.	15 min	28.3 klb	N/A
3	85° F.	5 min	28.3 klb	25 F/min

The force of 28.3 klb corresponds to a press pressure of 1000 psi.

SPEMs produced via this example were FMI 126-16N, FMI 126-16O. See Table 5 for various results obtained from these SPEMs. The low IECs obtained from these films and the correspondingly high resistances are a function of the low loading of ion-conductor in the composite structure. It is anticipated that using more concentrated solutions of the ion-conductor in imbibing the substrate will lead to composite SPEMs of low enough resistances for the applications described. The stability of the lateral dimensions of these Nafion® based composite membranes presents a significant improvement over unsupported Nafion® 117 films (which show in plane dimensional changes on hydration of about 20%). Given the exceptional strength of the PBO substrate, the mechanical properties of the composites are well in excess of current state of the art fuel cell membranes.

Example 12

Fabrication of SPEM

Using PBO and sulfonated Ultrason®

Ion-conducting membranes fabricated in this example followed closely those in Example 9. The substrate utilized was PBO film extruded and solvent exchanged into NMP as described above in the general procedure. The ion-conducting polymer (75% sulfonated Ultrason purified—Na+ form) was synthesized according to Example 3 given above.

Microporous PBO, having been exchanged into NMP without collapse of the pores, was added to a solution of the sulfonated 75% sulfonated Ultrason polymer in NMP (8 or 12 wt. %). After twelve or more hours at room temperature the films were removed, stretched in tensioning rings, and dried of the solvent (see general procedure outlined above). Specifically, the sulfonated Radel R®/PBO films were dried in a low humidity chamber (<5% RH) for 1 to 2 days, vacuum dried in an oven heated from below 60° C. to 140° C.

Low Temperature Vacuum Pressing


Step	Temp.	Hold Time	Force	Ramp Rate

1	125° F.	20 min	2.9 klb	15 F/min
2	200° F.	20 min	2.9 klb	15 F/min
3	275° F.	20 min	2.9 klb	15 F/min
4	390° F.	20 min	2.9 klb	15 F/min
5	85° F.	—	2.9 klb	25 F/min

High Temperature Hot Press


Step	Temp.	Hold Time	Force	Ramp Rate

1	390° F.	15 min	28.3 klb	15 F/min
2	85° F.	5 min	28.3 klb	25 F/min

The force of 28.3 klbf corresponds to a press pressure of 1000 psi.

SPEMs produced via this example were FMI 126-08E, FMI 126-08F. See Table 5 for various results obtained from SPEMs made via this procedure.

Example 13

Fabrication of SPEM Using Cast PBO and Sulfonated Radel R®

Ion-conducting membranes can be fabricated as illustrated above in Example 12 with use of microporous PBO substrates obtained by the film casting techniques enumerated in the general procedures. These films were solvent exchanged from water into NMP, after the coagulation and rinsing. These microporous films were placed in ion conductor solutions (5-10 wt. % in NMP) and allowed to equilibrate for a day or more. Once infused with the ion conductor solution, the films were placed in tensioning rings and dried of the solvent. In the case of the sulfonated Radel R®/cast PBO films, samples were first dried in a low humidity chamber for 1 or more days at room temperature and then vacuum dried at 200° C.

After all the solvent had been dried from the membrane, the composite structure was hot pressed using methods similar to those in Example 9. SPEMs produced via this example were FMI 126-AY1, FMI 126-82BE and FMI 126-d91BO. See Table 5 for various properties of these composite membranes.

Example 14

Fabrication of SPEM Using Microporous Poly(ether sulfone) Substrate and Nafion®1100EW Ion Conductor

A commercially available microporous membrane made of poly(ether sulfone) was obtained from Memtec (BTS-80), with a 0.02 micron pore size and an approximate porosity (void volume) of 80%. This microporous membrane was soaked in a Nafion® 1100 EW solution (water/alcohol solvent). A vacuum was drawn on the solution and film to degas and completely fill the pores. The film was then removed from the solution and vacuum dried (to approx. 100° C.). This process was repeated two more times, each time the film was added to the solution, vacuum degassed, and dried of solvent. Finally, the ion-conducting component was placed in the sodium salt form by soaking in saturated sodium bicarbonate solution by repeated rinsing followed by vacuum drying. Properties of a SPEM produced using the above method are shown for FMI 126-79BB in Table 5.

Example 15

Crosslinking of Sulfonated PPSU

Ion-conducting polymeric samples can be crosslinked in the acid (H+) form to improve ICP stability. Normally, crosslinking is performed in vacuum, to exclude oxygen from the system (can cause ICP charring). For example, SPPSU was crosslinked in a vacuum oven preheated to temperatures of 200, 225 and 250° C. for durations of up to 8 hours. Under these conditions, samples showed a slight IEC loss (˜10%), and little improvement in long term stability (peroxide test). More severe conditions were employed by exposing samples to 250° C. in full vacuum for more than 20 hours. Peroxide testing did not show any considerable difference between SPPSU crosslinked films and SPPSU controls until heated for at least 32 hours. The SPPSU films crosslinked at 250° C. for 32 hours and 72 hours maintained their film integrity during the peroxide accelerated life test. The IEC of these test samples decreased significantly. Specifically, a loss of 63% (1.90 to 0.69 meg/g) for the 32 hour sample and a loss of 73% (1.90 meg/g to 0.51 meq/g) for the 72 hour crosslinked SPPSU films was calculated. It is anticipated that many of the SO₃H acid groups form aromatic sulfone (Ar—SO₂—Ar) crosslinks between polymer chains. This trend confirms that crosslinking (H+ form) of sulfonated polymers can be used to improve long term membrane stability.

Example 16Synthesis of Water Soluble Sulfonated Polyphenyl Sulfone

Bis(3-sulfonato, 4-fluorophenyl)sulfone monomer was reacted with 4-4′-thiobisbenzene thiol in the presence of potassium carbonate to prepare SPSS-100 water soluble sulfonated poly(phenylene sulfide sulfone) polymer. A three-necked round-bottomed flask was equipped with a mechanical stirrer, nitrogen adapter and Dean-Stark trap with condenser. The flask was charged with 13.747 g (30 mmol) sulfonated difluorodiphenyl sulfone, 7.512 g (30 mmol) of 4,4′-thiobisbenzene thiol, 9.54 g (69 mmol) potassium carbonate, 32 ml of toluene and 60 ml of N-methyl pyrrolidinone. The mixture was then stirred under nitrogen at 155° C. for 8 hours. Any water that collected in the Dean-Stark trap was drained and the temperature was increased to 160° C. for 24 hours. The temperature was increased to 170° C. and heating was continued for another 24 hours. The reaction mixture was cooled and the polymer was precipitated from methanol. The polymer precipitant was filtered and dried at 100° C. under vacuum overnight. To clean the polymer, the solid was dissolved at about 4 wt % in water and dialyzed using 1K SpectraPor® dialysis tubing through three rinses over the span of two days. The cleaned polymer was dried again and weighed. Elemental analysis was used to confirm the identity of the polymer and found it to be a dihydrate. In order to exchange the polymer to its acid form, it was re-dissolved in water at 1 wt % and run through a column of Amberlyst® ion exchange resin. The cleaned and converted polymer was dried under vacuum at 100° C. Titration of the water soluble polymers gave the expected average ion exchange capacity (IEC) of 3.2 milliequivalents of H⁺/g of polymer (see Table 6) and thermogravimetric analysis (TGA) showed clean materials with the anticipated sulfonic acid groups lost at roughly 250° C.

TABLE 6

EC values of SPSS-100 batches

	IEC
	(mequiv of
Polymer	H⁺/g of	% from
#	polymer)	theoretical

412-54-1	3.1	3.125
412-54-2	3.1	3.125
412-67-1	3.154	1.4375
412-74-1	3.241	−1.28125
412-74-3	3.16	1.25
412-77-2	3.1	3.125

Example 2Imbibing Water Soluble Ion Conducting Polymer into PBO

PEMs were prepared by an imbibing process during which porous unconsolidated PBO membranes were soaked in aqueous solutions of ICP. To imbibe with water-soluble ICP, PBO membranes were first tensioned in stainless steel rings. The films were then soaked in solutions 20 wt % ICP in water at 80° C. overnight. This allowed the ICP concentration in the membrane pores to reach equilibrium with the bulk solution concentration. The films were pulled out of the imbibing solution and excess surface ICP was removed. Any desired surface treatment was then performed. Surface treatment could include application of a thin layer by immersion of the PEM in a 2% Nafion/dimethyl acetamide (DMAc) solution. The samples were dried to 175° C. on a ramp and soak cycle (see below)

PEM Drying Cycle:

- 1. Ramp (1 deg/min) to 75° C. and soak for 60 minutes
- 2. Ramp(1 deg/min) to 100° C. and soak for 60 minutes
- 3. Ramp(1 deg/min) to 150° C. and soak for 60 minutes
- 4. Ramp(1 deg/min) to 175° C. and soak for 60 minutes

Collapse of the structure upon drying yielded a fully densified PEM. Weight calculations showed PEMs are comprised of an average of 50-60% ion-conducting polymer. Area specific resistance (ASR) was tested for the SPSS-100 imbibed PEMs and found to be between 90 and 240 mohms*cm². These data indicate successful imbibition of the water soluble ICP into the PBO membranes.

Example 3Imbibing Water Soluble Ion Conducting Polymer into PBZT

PEMs were prepared by an imbibing process during which porous unconsolidated PBZT membranes were soaked in solutions of ICP. To imbibe with water-soluble ICP, PBZT membranes were first tensioned in stainless steel rings. The films were then soaked in solutions of water and 20 wt % ICP at 80° C. overnight. This allowed the ICP concentration in the membrane pores to reach equilibrium with the bulk solution concentration. The films were pulled out of the imbibing solution and any excess surface ICP was removed. Any desired surface treatment was then performed. Surface treatment could include application of a thin layer of Nafion® by immersion of the PEM in a 2% Nafion/DMAc solution. The samples were dried to 175° C. on a ramp and soak cycle (see below)

PEM Drying Cycle:

Collapse of the structure upon drying yielded a fully densified PEM. Weight calculations showed PEMs are comprised of an average of 60-70% ion conducting polymer. ASRs for the SPSS-100 imbibed PEM's were found to be between 90 and 240 mohms*cm². These data indicate successful imbibition of the water soluble ICP into the PBZT membranes.

Example 4Comparison of PBO Imbibed with Water Soluble Polymer Versus Water Insoluble Polymer

PEMs were prepared to compare the use of SPSS-100, a water soluble polymer to SPES-40, an organic solvent-soluble polymer as the imbibed ion-conducting polymer in PBO substrates. These PEMs were evaluated for conductivity and mechanical strength. Chemical structures of the two polymers are shown in Table 7. The water soluble polymer is inherently more brittle and was thus expected to reduce the mechanical strength of the PEM. For comparable PEMs in the dry state, the tensile strength was seen to drop from 28 ksi for SPES-40 imbibed film to 14 ksi for the SPSS-100 imbibed films, while the tensile modulus was 0.6 msi for SPES-40 imbibed film and 0.45 msi for the SPSS-100 imbibed films. While use of the water soluble polymer clearly does reduce the PEM strength, the SPSS-100 imbibed PEM's mechanical strength still makes it favorable for use as fuel cell membrane. The mechanical strength of Nafion is much lower, particularly when it is hydrated, indicating SPSS-100 imbibed PBO PEMs have improved strength over the state-of-the-art membranes. The use of the water soluble polymer as an ICP dramatically improves the ASR of our PEMs. PEMs imbibed with SPES-40 were found to have extremely high ASR of 3429 mohms*cm². However, using SPSS-100 decreased the ASR to 121 mohms*cm². This decrease in ASR and good mechanical strength indicate SPSS-100/PBO PEMs are good candidates for fuel cell membranes.

TABLE 7

Ion Conducting Polymers:

		Ave. %
ICP		Loading
type	ICP Structure	in PEM	ASR^a	IEC^b

SPSS-100	62	126	3.2

SPES-40	57.7	3429	1.28

^ameasured in mohms*cm²;
^bmequiv of H⁺/gram polymer.

TABLE 8

Table of PEMs

	ASR
	(mohms *	Tensile	Tensile
PEM	cm²)	Strength (ksi)	Modulus (msi)

Nafion 1135	101	5.25 dry	0.034 dry
		3.95 hydrated	0.003 hydrated
SPES-40-imbibed PBO	3429	28 dry	0.6 dry
SPES-100-imbibed PBO	126	14 dry	0.45 dry
		14 hydrated	0.3 hydrated

Example 5MEA Preparation

Using SPSS-100/PBO-based PEMs prepared according to example 2, membrane-electrode assemblies (MEAs) were made by hot pressing Nafion® electrodes with standard techniques. PEMs for MEA fabrication were prepared with a Nafion® surface treatment (see example 2 above). The catalyst ink was prepared by combining 125 mg of a 5% Nafion® solution with 250 mg of a 1:1 IPA/H₂O solution in a 7 ml sample vial. The alcohol serves as a solvent for Nafion® and water is used to slow down the overall evaporation rate and allow increased working time. The mixture was placed in an ice bath on a mixing plate to further slow down solvent evaporation. In cases where the mixture gelled, an additional 125 mg of IPA/ H₂O solution was added. The catalyst used was a 20 wt. % Platinum supported on carbon black (Vulcan XC-72) powder. On a filter paper, 25 mg of catalyst powder was weighed out. The catalyst powder was slowly added to the aqueous Nafion solution. The ink was then placed in an ultrasonic mixer (still in ice bath) for 10 minutes in order to give a good dispersion of the catalyst powder in the solvent. Lastly, the ink solution was placed on a mixing plate for 30 minutes in order to ensure complete mixing.

To prepare the MEA, the ink was then painted onto commercially available 5 cm²gas diffusion layers (GDLs) to achieve Pt loadings of 0.4-0.5 mg/cm². The prepared PEMs were sandwiched between these painted GDLs (with electrodes facing the PEM) and 3 in×3 in Teflon® gaskets, and then hot pressed using the following conditions:

1. Heat press to 100° C. and insert MEA
2. Hold for 5 minutes
3. Increase force to 4000 lbs and temperature to 140° C.
4. Hold for 90 seconds
5. Remove from press, lay on bench top, and apply force via lead brick during cooling
6. Wait 10-15 minutes before removing from aluminum plates.
Polarization curves were run on the MEAs to collect performance data. A typical polarization curve for such an MEA is shown in FIG. 3.